TY - CHAP

T1 - Thermomechanical Deformation of Complex Workpieces in Milling and Drilling Processes

AU - Denkena, B.

AU - Maaß, P.

AU - Schmidt, A.

AU - Niederwestberg, D.

AU - Vehmeyer, J.

AU - Niebuhr, C.

AU - Gralla, P.

N1 - Funding Information: Acknowledgements The presented results have been obtained within the research project “Ther-momechanical Deformation of Complex Workpieces in Drilling and Milling Processes” (DE 447/ 90-3, MA 1657/21-3) within the DFG Priority Program 1480 “Modeling, Simulation and Compensation of Thermal Effects for Complex Machining Processes”. The authors would like to thank the DFG for its financial and organizational support of the project.

PY - 2017/9/2

Y1 - 2017/9/2

N2 - In this chapter the work of an interdisciplinary collaboration for modeling thermomechanical deformations in dry milling and drilling processes is presented. The simulation based approach allows the prediction of structural workpiece deformation due to thermal effects occurring during the machining process. Geometric changes of the workpiece volume and the current engagement of tool and workpiece are included in the developed model. The model is applied for the optimization of NC paths with respect to workpiece deformations. The combined model is assembled by individual sub-models, which are coupled to account for interactions with each other. A dexel model is applied for contact zone analysis of tool and workpiece and also allows efficient geometric modeling of the workpiece surface. Geometric process variables of the contact zone are passed to the process model which provides thermal and mechanical loads for the thermomechanics. The thermomechanical behaviour is numerically approximated using finite elements on the time depending co-domain of the dexel model together with thermal and mechanical loads provided by the process model. In all, a closed loop between Boolean material removal, process forces, heat flux and thermo-elastic deformation is established and allows an accurate prediction of workpiece deformation and shape deviations. Furthermore, the simulation operates as a forward model for an NC path optimization. A significant improvement of form deviation is achieved with the approach.

AB - In this chapter the work of an interdisciplinary collaboration for modeling thermomechanical deformations in dry milling and drilling processes is presented. The simulation based approach allows the prediction of structural workpiece deformation due to thermal effects occurring during the machining process. Geometric changes of the workpiece volume and the current engagement of tool and workpiece are included in the developed model. The model is applied for the optimization of NC paths with respect to workpiece deformations. The combined model is assembled by individual sub-models, which are coupled to account for interactions with each other. A dexel model is applied for contact zone analysis of tool and workpiece and also allows efficient geometric modeling of the workpiece surface. Geometric process variables of the contact zone are passed to the process model which provides thermal and mechanical loads for the thermomechanics. The thermomechanical behaviour is numerically approximated using finite elements on the time depending co-domain of the dexel model together with thermal and mechanical loads provided by the process model. In all, a closed loop between Boolean material removal, process forces, heat flux and thermo-elastic deformation is established and allows an accurate prediction of workpiece deformation and shape deviations. Furthermore, the simulation operates as a forward model for an NC path optimization. A significant improvement of form deviation is achieved with the approach.

UR - http://www.scopus.com/inward/record.url?scp=85166655082&partnerID=8YFLogxK

U2 - 10.1007/978-3-319-57120-1_11

DO - 10.1007/978-3-319-57120-1_11

M3 - Contribution to book/anthology

T3 - Lecture Notes in Production Engineering

SP - 219

EP - 250

BT - Thermal Effects in Complex Machining Processes

ER -